Complete steric exclusion of ions and proton transport through confined monolayer water

Gopinadhan, K.; Hu, Sheng; Esfandiar, Ali; Lozada-Hidalgo, M.; Wang, FengChao; Yang, Qiong; Tyurnina, Anastasia V.; Keerthi, Ashok; Radha, Boya; Geǐm, A. K.

doi:10.1126/science.aau6771

Cited by 223 publications

(250 citation statements)

References 54 publications

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“…To achieve it, nature utilizes aquaporins, membrane proteins with 0.3 nm wide channels that efficiently transport water molecules in a single‐file motion across cell membranes but block all ionic species . This collective movement of water in natural nanoconduits stimulates the development of artificial membranes to provide clean water for mankind, and the key is to create similarly sized channels . Commercially used osmosis membranes are mostly derived from polymers whose chains are often randomly arranged leading to a broad pore size distribution .…”

Section: Ion Transport Through a Single Channel At 1 M Kclmentioning

confidence: 99%

Ultrahigh Ionic Exclusion through Carbon Nanomembranes

Yang

Hillmann

et al. 2020

Advanced Materials

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The collective “single‐file” motion of water molecules through natural and artificial nanoconduits inspires the development of high‐performance membranes for water separation. However, a material that contains a large number of pores combining rapid water flow with superior ion rejection is still highly desirable. Here, a 1.2 nm thick carbon nanomembrane (CNM) made from cross‐linking of terphenylthiol (TPT) self‐assembled monolayers is reported to possess these properties. Utilizing their extremely high pore density of 1 sub‐nm channel nm−2, TPT CNMs let water molecules rapidly pass, while the translocation of ions, including protons, is efficiently hindered. Their membrane resistance reaches ≈104 Ω cm2 in 1 m Cl− solutions, comparable to lipid bilayers of a cell membrane. Consequently, a single CNM channel yields an ≈108 higher resistance than pores in lipid membrane channels and carbon nanotubes. The ultrahigh ionic exclusion by CNMs is likely dominated by a steric hindrance mechanism, coupled with electrostatic repulsion and entrance effects. The operation of TPT CNM membrane composites in forward osmosis is also demonstrated. These observations highlight the potential of utilizing CNMs for water purification and opens up a simple avenue to creating 2D membranes through molecular self‐assembly for highly selective and fast separations.

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Section: Ion Transport Through a Single Channel At 1 M Kclmentioning

confidence: 99%

Ultrahigh Ionic Exclusion through Carbon Nanomembranes

Yang

Hillmann

et al. 2020

Advanced Materials

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“…Recently, graphene oxide (GO) has become a promising membrane material owing to its impressive separation performance [22][23][24][25]. GO membranes possess ultrafast water transport properties and extraordinary water adsorption characteristics [26,27].…”

Section: Introductionmentioning

confidence: 99%

Graphene oxide quantum dots embedded polysulfone membranes with enhanced hydrophilicity, permeability and antifouling performance

Zhao

et al. 2019

Sci. China Mater.

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Graphene oxide (GO) has been demonstrated to be an effective hydrophilic nanofiller to modify the polymeric membranes when forming a mixed matrix structure. GO quantum dots (QDs) are promising candidates to fully exert the rich oxygen containing functional groups due to their unique size induced edge effects. In this work, GO QDs modified polysulfone (PSF) ultrafiltration (UF) membranes were prepared by phase inversion method with various GO QDs loadings (0.1-0.5 wt.%). A proper amount of GO QDs addition led to a more porous and hydrophilic membrane structure. With 0.3 wt.% GO QDs, the membranes showed a 60% increase in permeability (130.54 vs. 82.52 LMH bar -1 ).The pristine PSF membranes had a complete cutoff of bovine serum albumin molecules and it was well maintained with GO QDs incorporated. The membranes with 0.5 wt.% GO QDs exhibited the highest flux recovery ratio of 89.7% and the lowest irreversible fouling of 10.3% (54.5% and 33.3% for the pristine PSF membranes). Our results proved that GO QDs can function as effective nanofillers to enhance the hydrophilicity, permeability and antifouling performance of PSF UF membranes.

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“…This contributes to the establishment of a robust theoretical framework where quantitative analysis is allowed. Indeed, this requirement has been well reflected by the persistent effort toward the manufacturing of nanochannels with precisely reduced sizes and well‐defined geometries . Understanding and proper interpretation of experimental results can only be made possible if the channel structures are quantifiable.…”

Section: Desirable Materials Characteristics For Nanoionics Research mentioning

confidence: 99%

“…Due to the atomic thickness of the 2D monolayer materials, the extracting method is capable of constructing nanochannels with precision at unprecedented angstrom‐level . Such a well‐defined nanochannel is perfectly suited for fundamental study of ion transport involved in angstrom‐scale confinement …”

Section: Constructing Void Nanostructures For Nanoionics From 2d Nanomentioning

confidence: 99%

“…This strategy allows the cost‐effective production of 2D‐NLMs with tunable nanochannels at large scale . Given the ease of synthesis, high‐level structural tunability and versatility, 2D‐NLMs have been extensively explored for confined molecular and ion transport by many research groups including Gao, Geim, Gogotsi, Guo, Huang, Jin, Li, Mi, Nair, Ren, Zhu, and more. The following section will lay out some of the typical attributes of 2D‐NLMs obtained by cascading to correlate with the advances in solvation‐involved nanoionics research.…”

Section: Constructing Void Nanostructures For Nanoionics From 2d Nanomentioning

confidence: 99%

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Solvation‐Involved Nanoionics: New Opportunities from 2D Nanomaterial Laminar Membranes

et al. 2019

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Nanoporous laminar membranes composed of multilayered 2D nanomaterials (2D‐NLMs) are increasingly being exploited as a unique material platform for understanding solvated ion transport under nanoconfinement and exploring novel nanoionics‐related applications, such as ion sieving, energy storage and harvesting, and in other new ionic devices. Here, the fundamentals of solvation‐involved nanoionics in terms of ionic interactions and their effect on ionic transport behaviors are discussed. This is followed by a summary of key requirements for materials that are being used for solvation‐involved nanoionics research, culminating in a demonstration of unique features of 2D‐NLMs. Selected examples of using 2D‐NLMs to address the key scientific problems related to nanoconfined ion transport and storage are then presented to demonstrate their enormous potential and capabilities for nanoionics research and applications. To conclude, a personal perspective on the challenges and opportunities in this emerging field is presented.

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Complete steric exclusion of ions and proton transport through confined monolayer water

Cited by 223 publications

References 54 publications

Ultrahigh Ionic Exclusion through Carbon Nanomembranes

Ultrahigh Ionic Exclusion through Carbon Nanomembranes

Graphene oxide quantum dots embedded polysulfone membranes with enhanced hydrophilicity, permeability and antifouling performance

Solvation‐Involved Nanoionics: New Opportunities from 2D Nanomaterial Laminar Membranes

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